Eulerian integral associated with product of three multivariable Aleph-functions and a class of polynomials

Eulerian integral associated with product of three multivariable

Aleph-functions and a class of polynomials

1 Teacher in High School , France E-mail : [email protected]

ABSTRACT

The present paper is evaluated a new Eulerian integral associated with the product of three multivariable Aleph-functions , a generalized Lauricella function ,a class of multivariable polynomials with general arguments . We will study the cases concerning the multivariable I-function defined by Sharma et al [2] and Srivastava-Daoust polynomial [3].

Keywords: Eulerian integral, multivariable I-function, generalized Lauricella function of several variables, multivariable Aleph-function, generalized hypergeometric function, class of polynomials, Srivastava-Daoust polynomial

2010 Mathematics Subject Classification. 33C99, 33C60, 44A20

1. Introduction

In this paper, we consider a general class of Eulerian integral concerning the product of three Multivariable Aleph-functions and a general class of multivariable polynomials defined by Srivastava et al [6].

The Aleph-function of several variables generalize the multivariable I-function defined by Sharma and Ahmad [2] , itself is an a generalisation of G and H-functions of several variables defined by Srivastava et al [6]. The multiple Mellin-Barnes integral occuring in this paper will be referred to as the multivariables Aleph-function throughout our present study and will be defined and represented as follows.

We define :

= (1.1)

with

(1.2)

Suppose , as usual , that the parameters

;

;

with , ,

are complex numbers , and the and are assumed to be positive real numbers for standardization purpose such that

(1.4)

The reals numbers are positives for to , are positives for to

The contour is in the -p lane and run from to where is a real number with loop , if necessary ,ensure that the poles of with to are separated from those of

with to and with to to the left of the

contour . The condition for absolute convergence of multiple Mellin-Barnes type contour (1.9) can be obtained by extension of the corresponding conditions for multivariable H-function given by as :

, where

, with , , (1.5)

The complex numbers are not zero.Throughout this document , we assume the existence and absolute convergence conditions of the multivariable Aleph-function.

We may establish the the asymptotic expansion in the following convenient form :

,

,

where : and

Serie representation of Aleph-function of variables is given by

(1.6)

Where , are given respectively in (1.2), (1.3) and

which is valid under the conditions (1.7)

for

We have :

= (1.8)

with

(1.9)

and (1.10)

;

;

with , ,

are complex numbers , and the and are assumed to be positive real numbers for standardization purpose such that

(1.11)

The reals numbers are positives for to , are positives for to

The contour is in the -p lane and run from to where is a real number with loop , if necessary ,ensure that the poles of with to are separated from those of

with to and with to to the left of the

contour . The condition for absolute convergence of multiple Mellin-Barnes type contour (1.9) can be obtained by extension of the corresponding conditions for multivariable H-function given by as :

, where

, with , , (1.12)

The complex numbers are not zero.Throughout this document , we assume the existence and absolute convergence conditions of the multivariable Aleph-function.

We may establish the the asymptotic expansion in the following convenient form :

,

,

where : and

We will use these following notations in this paper

W (1.14)

(1.15)

(1.16)

(1.17)

(1.18)

The multivariable Aleph-function write :

(_1.19)

Consider the Aleph-function of s variables

= (1.20)

with

(1.21)

Suppose , as usual , that the parameters

;

;

with , ,

are complex numbers , and the and are assumed to be positive real numbers for standardization purpose such that

(1.23)

The reals numbers are positives for , are positives for

The contour is in the -p lane and run from to where is a real number with loop , if necessary ,ensure that the poles of with to are separated from those of

with to and with to to the left of the

contour . The condition for absolute convergence of multiple Mellin-Barnes type contour (1.9) can be obtained by extension of the corresponding conditions for multivariable H-function given by as :

, where

, with , , (1.24)

The complex numbers are not zero.Throughout this document , we assume the existence and absolute convergence conditions of the multivariable Aleph-function.

We may establish the the asymptotic expansion in the following convenient form :

,

,

where : and

; (1.25)

(1.26)

(1.27)

(1.28)

(1.29)

(1.30)

The multivariable Aleph-function write :

(1.31)

Srivastava and Garg [4] introduced and defined a general class of multivariable polynomials as follows

= (1.32)

The coefficients are arbitrary constants, real or complex.

2. Integral representation of generalized Lauricella function of several variables

The following generalized hypergeometric function in terms of multiple contour integrals is also required [5 ,page 39 eq .30]

(2.1)

where the contours are of Barnes type with indentations, if necessary, to ensure that the poles of

are separated from those of . The above result (1.23) can be easily established by an appeal to the calculus of residues by calculating the residues at the poles of

(2.2)

where

and is a particular case of the generalized Lauricella function introduced by Srivastava-Daoust[3,page 454] and [5] given by :

(2.3)

Here the contour are defined by starting at the point and terminating at the

point with and each of the remaining contour run from to

(2.2) can be easily established by expanding by means of the formula :

(2.4)

integrating term by term with the help of the integral given by Saigo and Saxena [1, page 93, eq.(3.2)] and applying the definition of the generalized Lauricella function [3, page 454].

In this section , we note :

;

(3.1)

(3.3)

(3.4) j

(3.5) j

(3.6)

(3.7)

(3.8)

(3.9)

(3.10)

where

(3.11)

(3.12)

(3.13)

(3.14)

We obtain the Aleph-function of variables. The quantities and are

defined above.

(A ) ,

(B) See the section 1

(C)

(D)

(E)

(F)

(G)

, with ,

,

, with ,

(H)

(I)

Proof

To prove (3.14), first, we express in serie the multivariable Aleph-function with the help of (1.6), a class of multivariable polynomials defined by Srivastava et al [4] in serie with the help of (1.32) and we interchange the order of summations and t-integral (which is permissible under the conditions stated). Expressing the Aleph-functions of r-variables and s-variables in terms of Mellin-Barnes type contour integral with the help of (1.8) and (1.20) respectively and interchange the order of integrations which is justifiable due to absolute convergence of the integral involved in the process . Now collect the power of Now collect the power of with with

and collect the power of

and collect the power of with with . Use the equations (2.2) and (2.3) and express the result in. Use the equations (2.2) and (2.3) and express the result in Mellin-Barnes contour integral. Interpreting the

Mellin-Barnes contour integral. Interpreting the dimensional Mellin-Barnes integral in multivariable dimensional Mellin-Barnes integral in multivariable Aleph-function ,we obtain the equation (3.14).

Aleph-function ,we obtain the equation (3.14).

Remarks Remarks

If a)

If a) ; b) ; b) , we obtain the similar formulas that, we obtain the similar formulas that (3.14) with the corresponding simplifications.

(3.14) with the corresponding simplifications.

4. Particular cases

a) If

a) If , the multivariable Aleph-functions of r and s-variables reduces, the multivariable Aleph-functions of r and s-variables reduces to multivariable I-functions of r and s-variables defined by Sharma and al [2] respectively and we have

under the same conditions and notations that (3.14) with

under the same conditions and notations that (3.14) with

b)

b) If If = = (4.2) (4.2)

then the general class of multivariable polynomial

then the general class of multivariable polynomial reduces to generalized Lauricella function reduces to generalized Lauricella function defined by Srivastava et al [3]. We have

(4.3)

under the same notations and conditions that (3.14)

where

where , , is defined by (4.2) is defined by (4.2)

Remark:

By the following similar procedure, the results of this document can be extented to product of any finite number of By the following similar procedure, the results of this document can be extented to product of any finite number of multivariable Aleph-functions and a class of multivariable polynomials defined by Srivastava et al [4].

multivariable Aleph-functions and a class of multivariable polynomials defined by Srivastava et al [4].

5. Conclusion

formula from which, upon specializing the parameters, as many as desired results involving the special functions of one and several variables can be obtained.

REFERENCES

[1] Saigo M. and Saxena R.K. Unified fractional integral formulas for the multivariable H-function I. J.Fractional Calculus 15 (1999), page 91-107.

[2] Sharma C.K.and Ahmad S.S.: On the multivariable I-function. Acta ciencia Indica Math , 1994 vol 20,no2, p 113-116.

[3] Srivastava H.M. and Daoust M.C. Certain generalized Neumann expansions associated with Kampé de Fériet function. Nederl. Akad. Wetensch. Proc. Ser A72 = Indag Math 31(1969) page 449-457.

[4] Srivastava H.M. And Garg M. Some integral involving a general class of polynomials and multivariable H-function. Rev. Roumaine Phys. 32(1987), page 685-692.

[5] Srivastava H.M. and Karlsson P.W. Multiple Gaussian Hypergeometric series. Ellis.Horwood. Limited. New-York, Chichester. Brisbane. Toronto , 1985.

[6] H.M. Srivastava and R.Panda. Some expansion theorems and generating relations for the H-function of several complex variables. Comment. Math. Univ. St. Paul. 24(1975), p.119-137.

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